Estimating the heritability of thermal tolerance in Acropora cervicornis and the physiological basis of adaptation that correlates to survival at elevated temperatures

Yetsko, Kelsey L

01 January 2018

Human activities have substantially increased the atmospheric concentrations of greenhouse gases, resulting in warmer ocean temperatures that are having a negative impact on reef corals, which are highly susceptible to changes in temperature. Understanding the degree to which species vary in their tolerance to elevated temperatures and whether this variation is heritable is important in determining their ability to adapt to climate change. In order to address this, Acropora cervicornis fragments from 20 genetically distinct colonies were kept at either ambient or elevated temperatures, and mortality was monitored for 26 days. Heritability of thermal tolerance was estimated using a clonal method comparing the difference in lifespan within and among clones in a one-way ANOVA, as well as a marker based method using the program MARK (Ritland 1996) to estimate relatedness between colonies. To understand the physiological basis of thermal tolerance, tissue samples from both treatments were taken after 12 hours to investigate gene expression associated with sub-lethal temperature stress at both the mRNA and the protein level. The results revealed that this population of A. cervicornis has a relatively high amount of total genetic variation in thermal tolerance (H2 = 0.528), but low additive genetic variation for this trait (h2 = 0.032). In addition, both gene expression and protein expression among colonies were highly variable and did not show consistent patterns related to differences in thermal tolerance among colonies. These results reveal that this population of A. cervicornis may have a limited capacity to respond to projected increases in ocean temperatures. In addition, the results suggest that the molecular basis of thermal tolerance in this species is complex and that there are potentially many genotypic combinations that can result in a heat-tolerant phenotype.

Thesis

University of North Florida

UNF

coral

Acropora cervicornis

thermal tolerance

adaptation

gene expression

climate change

Cellular and Molecular Physiology

Computational Biology

Ecology and Evolutionary Biology

Molecular Genetics

Hydrogen Sulfide Regulation of Kir Channels

Ha, Junghoon

01 January 2017

Inwardly rectifying potassium (Kir) channels establish and regulate the resting membrane potential of excitable cells in the heart, brain and other peripheral tissues. Phosphatidylinositol- 4,5-bisphosphate (PIP2) is a key direct activator of ion channels, including Kir channels. Gasotransmitters, such as carbon monoxide (CO), have been reported to regulate the activity of Kir channels by altering channel-PIP2 interactions. We tested, in a model system, the effects and mechanism of action of another important gasotransmitter, hydrogen sulfide (H2S) thought to play a key role in cellular responses under ischemic conditions. Direct administration of sodium hydrogen sulfide (NaHS), as an exogenous H2S source, and expression of cystathionine γ-lyase (CSE), a key enzyme that produces endogenous H2S in specific brain tissues, resulted in comparable current inhibition of several Kir2 and Kir3 channels. A “tag switch” assay provided biochemical evidence for sulfhydration of Kir3.2 channels. The extent of H2S regulation depended on the strength of channel-PIP2 interactions: H2S regulation was attenuated when strengthening channel-PIP2 interactions and was increased when channel-PIP2 interactions were weakened by depleting PIP2 levels via different manipulations. These H2S effects took place through specific cytoplasmic cysteine residues in Kir3.2 channels, where atomic resolution structures with PIP2 gives us insight as to how they may alter channel-PIP2 interactions. Mutation of these residues abolished H2S inhibition, and reintroduction of specific cysteine residues into the background of the mutant lacking cytoplasmic cysteine residues, rescued H2S inhibition. Molecular dynamics simulation experiments provided mechanistic insights as to how sulfhydration of specific cysteine residues could lead to changes in channel-PIP2 interactions and channel gating.

Hydrogen sulfide

potassium channels

PIP2

phosphoinositide

stroke

ischemia

phosphatidylinositol 4

5-bisphosphate (PIP2)

Inwardly rectifying K+ (Kir) Channels

GIRK channels

KATP channels

Gasotransmitters

Cellular and Molecular Physiology

Medicine and Health Sciences

Molecular and Cellular Neuroscience

The Effects of Hydrostatic Pressure on Early Endothelial Tubulogenic Processes

Underwood, Ryan M.

01 January 2013

The effects of mechanical forces on endothelial cell function and behavior are well documented, but have not been fully characterized. Specifically, fluid pressure has been shown to elicit physical and chemical responses known to be involved in the initiation and progression of endothelial cell-mediated vascularization. Central to the process of vascularization is the formation of tube-like structures. This process—tubulogenesis—is essential to both the physiological and pathological growth of tissues. Given the known effects of pressure on endothelial cells and its ubiquitous presence in the vasculature, we investigated pressure as a magnitude-dependent parameter for the regulation of endothelial tubulogenic activity. To accomplish this, we exposed two- and three-dimensional bovine aortic endothelial cell (BAEC) cultures to static pressures of 0, 20, and 40 mmHg for 3 and 4 days. The most significant findings were: (1) cells in two-dimensional culture exposed to 20, but not 40, mmHg exhibited significantly (p < 0.05) increased expression of both VEGF-C and VEGFR-3, and (2) cells in three-dimensional culture exposed to 20, but not 40, mmHg exhibited significant (p > 0.05) increases in endothelial sprouting. These findings evidence the utility of pressure as a selective modulator of tissue microvascularization in vitro and implicates pressure as factor in pathological tubulogenesis in vivo.

tubulogenesis

angiogenesis

lymphangiogenesis

pressure

mechanotransduction

Biological Engineering

Biomechanics and biotransport

Biotechnology

Cell Biology

Cellular and Molecular Physiology

Circulatory and Respiratory Physiology

Molecular Identification and Functional Characteristics of Peptide Transporter 1 (PEPT1) in the Bonnethead Shark (Sphyrna tiburo)

Hart, Hannah

01 January 2015

Many elasmobranchs are considered top predators with worldwide distribution, and in general these fish play an important role in the transfer of energy from the lower to the upper trophic levels within the marine ecosystem. Despite this, little research has been done regarding the rates of prey ingestion, digestion, and the processes of energy and nutrient absorption. Specifically understudied is enzymatic digestion within the intestinal brush border, which functions to break down macromolecules into smaller subunits for luminal absorption across the gastrointestinal epithelium. Given their carnivorous diet, the present study sought to expand knowledge on nutrient intake in elasmobranchs by focusing on the uptake of products of protein metabolism. To accomplish this, sequence encoding Peptide Transporter 1 (PepT1), a protein found within the brush border membrane (BBM) of higher vertebrates that is responsible for the translocation and absorption of small peptides released during digestion by luminal and membrane-bound proteases, was molecularly identified in the bonnethead shark (Sphyrna tiburo) using degenerate primers based on conserved portions of known PEPT1 sequences from other vertebrates. Sequence encoding Peptide Transporter 2 (PepT2) was also isolated from the S. tiburo scroll valve intestine using the same methodology. PepT1 was then localized using immunocytochemistry with rabbit polyclonal anti-rat PEPT1 in the esophagus, stomach, duodenum, scroll valve intestine, rectum, and pancreas. Vesicle studies were used to identify the apparent affinity of the transporter, and to quantify the rate of uptake by its H+-dependent cotransporter properties, using 3H-glycylsarcosine as a model dipeptide. The results of this study provide insight into the rate and properties of food passage within S. tiburo, and can lead to future work on topics such as physiological regulation of protein metabolism and absorption and how it may vary in elasmobranchs that exhibit different feeding strategies.

Thesis

University of North Florida

UNF

Dissertations

Dissertations

Academic -- UNF -- Biology

Elasmobranch

Peptide transporter 1

Peptide transporter 2

scroll valve intestine

gastrointestinal tract

absorption

Cellular and Molecular Physiology

Integrative Biology

Marine Biology

The Role of Neurexins in Serotonin Signaling and Complex Behaviors

Cheung, Amy

27 April 2021

Extensive serotonin (5-HT) fiber innervation throughout the brain corroborates 5-HT’s modulatory role in numerous behaviors including social behavior, emotion regulation, and learning and memory. Abnormal brain 5-HT levels and function are implicated in Autism Spectrum Disorder (ASD) which often co-occurs with other neuropsychiatric conditions. While 5-HT therapeutics are used to treat ASD, variable improvements in symptomatology require further investigation of 5-HT-mediated pathology. Neurexins (Nrxns) are presynaptic cell adhesion molecules that maintain synapse function for proper neural circuit assembly. Given that aberrant Nrxn and 5-HT function independently contribute to signaling pathology and behavioral impairments, it is critical to understand how Nrxn-mediated 5-HT neurotransmission participates in pathological mechanisms underlying ASD. Using fluorescence in situ hybridization, I found that the three Nrxn genes (Nrxn1, Nrxn2, and Nrxn3) are differentially expressed in 5-HT neurons in the dorsal raphe nucleus (DRN) and median raphe nucleus which contain the primary source of 5-HT neurons in the brain. Our lab generated a mouse model with selective deletion of Nrxns in 5-HT neurons to investigate the function of Nrxns in 5-HT signaling. The loss of Nrxns at 5-HT release sites reduced 5-HT release in the DRN and hippocampus and altered 5-HT innervation in specific brain regions. The lack of 5-HTergic Nrxns also reduced sociability and increased depressive-like behavior in males. This mouse model provides mechanisms to shed new light on 5-HT neurotransmission in the generation of complex behaviors.

neurexin

serotonin

social behavior

depression

mouse

hippocampus

dorsal raphe nucleus

autism

brain

in situ hybridization

synapse

trans-synaptic adhesion

Animal Experimentation and Research

Behavioral Neurobiology

Cellular and Molecular Physiology

Cognitive Neuroscience

Molecular and Cellular Neuroscience

Effect of Oxygen-Limiting Tidal Conditions on Muscle Metabolism and Structure in the Giant Acorn Barnacle, Balanus nubilus

Grady, Katie O

01 December 2016

Crustacean muscle fibers are some of the largest cells in the animal kingdom, with fiber diameters in the giant acorn barnacle (Balanus nubilus) exceeding 3 mm. Sessile animals with extreme muscle sizes and that live in the hypoxia-inducing intertidal zone – like B. nubilus – represent ideal models for probing the effects of oxygen limitation on muscle cells. We investigated changes in metabolism and structure of B. nubilus muscle in response to: normoxic immersion, anoxic immersion, or air emersion, for acute (6h) or chronic (6h exposures twice daily for 2wks) time periods. Following exposure, we immediately measured hemolymph pO2, pCO2, pH, Na+, Cl-, K+, and Ca+ then excised tergal depressor (TD) and scutal adductor (SA) muscles to determine citrate synthase (CS) activity, lactate dehydrogenase (LDH) activity, and D-lactate levels. We also prepared a subset of SA and TD muscles from the chronic barnacles for histological analysis of fiber diameter (Feret’s), cross-sectional area (CSA), mitochondrial distribution and relative density, as well as nuclear distribution and myonuclear domain size. There was a significant decrease in hemolymph pO2 and pCO2 following acute and chronic anoxic immersion, whereas air emersion pO2 and pCO2 was comparable to normoxic levels. Fiber CSA and diameter did not change significantly in either tissue, while myonuclear domain size in SA muscle was significantly lower in the anoxic and emersion groups than the normoxic control. Neither CS, nor LDH activity, showed any significant treatment effect in either tissue, whereas both muscles had significantly higher D-lactate levels after air emersion following acute (though not chronic) exposure. Thus far, our findings indicate that B. nubilus experience a general reduction in aerobic metabolism under anoxia, emersion is only mildly oxygen-limiting, and that muscle plasticity is occurring during chronic emersion and anoxia.

Balanus nubilus

giant barnacle

anoxia

hypoxia

giant muscle cells

intertidal

metabolism

muscle plasticity

histology

Behavior and Ethology

Cell Biology

Cellular and Molecular Physiology

Comparative and Evolutionary Physiology

Developmental Biology

Integrative Biology

Marine Biology

Small RNAs and Argonautes Provide a Paternal Epigenetic Memory of Germline Gene Expression to Promote Thermotolerant Male Fertility: A Dissertation

Conine, Colin C.

26 September 2014

During each life cycle, gametes must preserve and pass on both genetic and epigenetic information, making the germline both immortal and totipotent. In the male germline the dramatic morphological transformation of a germ cell through meiosis, into a sperm competent for fertilization, while retaining this information is an incredible example of cellular differentiation. This process of spermatogenesis is inherently thermosensitive in numerous metazoa ranging from worms to man. Here, I describe the role of two redundant AGO-class paralogs, ALG-3/4, and their small RNA cofactors, in promoting thermotolerant male fertility in Caenorhabditis elegans. alg-3/4 double mutants exhibit temperature dependent sterility resulting from defective spermiogenesis, the postmeiotic differentiation of haploid spermatids into spermatozoa competent for fertilization. The essential Argonaute CSR-1 functions with ALG-3/4 to positively regulate target genes required for spermiogenesis by promoting transcription via a small RNA positive feedback loop. Our findings suggest that ALG-3/4 functions during spermatogenesis to amplify a small-RNA signal loaded into CSR-1 to maintain transcriptionally active chromatin at genes required for spermiogenesis and to provide an epigenetic memory of male-specific gene expression. CSR-1, which is abundant in mature sperm, appears to transmit this memory to offspring. Surprisingly, in addition to small RNAs targeting male-specific genes, we show that males also harbor an extensive repertoire of CSR-1 small RNAs targeting oogenesis-specific mRNAs. The ALG-3/4 small RNA pathway also initiates silencing small RNA signals loaded into WAGO vii Argonautes, which function to posttranscripitonally silence their target mRNAs. Silencing WAGO/small RNA-complexes are present in sperm and presumably transmitted to offspring upon fertilization. Together these findings suggest that C. elegans sperm transmit not only the genome but also epigenetic activating and silencing signals in the form of Argonaute/small-RNA complexes, constituting a memory of gene expression in preceding generations.

Argonaute Proteins

Caenorhabditis elegans

Genetic Epigenesis

Fertility

Germ Cells

Messenger RNA

Spermatogenesis

Temperature

Thermosensing

Dissertations, UMMS

Epigenesis, Genetic

RNA, Messenger

Cell Biology

Cellular and Molecular Physiology

Developmental Biology

Genetics

Molecular Biology

Intergenerational Effects of Nicotine in an Animal Model of Paternal Nicotine Exposure

Vallaster, Markus Parzival

07 August 2017

Environmental conditions imposed onto organisms during certain phases of their life cycles such as embryogenesis or puberty can not only impact the organisms’ own health, but also affect subsequent generations. The underlying mechanisms causing intergenerational phenotypes are not encoded in the genome, but the result of reversible epigenetic modifications. This work investigates in a mouse model the impact of paternal nicotine exposure on the next generation regarding addictive behavior modulation, metabolic changes, and molecular mechanisms. It provides evidence that male offspring from nicotine-exposed fathers (NIC offspring) is more resistant to lethal doses of nicotine. This phenotype is gender-specific and depends on short-term environmental challenges with low doses of nicotine prior to the LD50 application. The observed survival phenotype is not restricted to nicotine as drug of abuse, but also presents itself, when NIC offspring is challenged with a cocaine LD50 after acclimatization to low doses of either nicotine or cocaine. Functionally, NIC offspring metabolizes nicotine faster than control. Mechanistically, NIC offspring livers show global up-regulation of xenobiotic processing genes (XPG), an effect that is even more pronounced in primary hepatocyte cultures. Being known targets of Constitutive Androstane Receptor (CAR) and Pregnane X Receptor (PXR), these XPGs show higher baseline expression in naïve NIC offspring livers. Nicotine’s action on the brain’s reward circuitry does not appear to be of biological significance in our model system. Taken together, paternal nicotine exposure leads to a non-specific and conditional phenotype in male NIC offspring that may provide a general survival advantage against xenobiotic challenges.

chromosomes

epigenetics

genes

mouse

paternal effects

substance abuse

neuroscience

Behavioral Neurobiology

Cell Biology

Cellular and Molecular Physiology

Developmental Neuroscience

Genetics

Molecular Genetics

Genetic Deficiency of CD40 in Mice Exacerbates Metabolic Manifestations of Diet-induced Obesity: A Dissertation

Guo, Chang-An

23 April 2013

The past two decades have seen an explosive increase of obesity rates worldwide, with more than one billion adults overweight and 300 million of them obese. Obesity and its associated complications have become leading causes of morbidity and mortality in the United States and major contributing factors to the rising costs of national health care. The pathophysiology of obesity and type 2 diabetes in rodents and humans is characterized by low-grade inflammation and chronic activation of immune pathways in adipose tissue and liver. The CD40 receptor and its ligand, CD40L, initiate immune cell signaling promoting inflammation, but conflicting data on CD40L-null mice confound its role in obesity-associated insulin resistance. A clear understanding of how CD40 and its ligand communicate to regulate and sustain the inflammatory environment of obesity is lacking. Here we demonstrate that CD40 receptor deficient mice on a high-fat diet display the expected decrease in hepatic cytokine levels, but paradoxically exhibit liver steatosis, insulin resistance and glucose intolerance compared with their age-matched wild-type controls. Hyperinsulinemic-euglycemic clamp studies also demonstrated insulin resistance in glucose utilization by the CD40-null mice compared with wild-type mice. In contrast to liver, visceral adipose tissue in CD40 deficient animals harbors elevated cytokine levels and infiltration of inflammatory cells, particularly macrophages and CD8+ effector T cells. In addition, ex vivo explants of epididymal adipose tissue from CD40-null mice display elevated basal and isoproterenol-stimulated lipolysis, suggesting a potential increase of lipid efflux from visceral fat to the liver. These findings reveal that 1) CD40-null mice represent an unusual model of hepatic steatosis with reduced hepatic inflammation, and 2) CD40 unexpectedly functions in adipose tissue to attenuate the chronic inflammation associated with obesity, thereby protecting against hepatic steatosis.

Adipose tissue inflammation

CD40

CD8+ T cell

hepatic steatosis

insulin resistance

Dissertations, UMMS

Adipose Tissue

Antigens, CD40

Obesity

Fatty Liver

Insulin Resistance

Inflammation

Biochemistry

Cellular and Molecular Physiology

Endocrinology

Immunopathology

Molecular Genetics

Understanding Drug Resistance and Antibody Neutralization Escape in Antivirals: A Dissertation

Prachanronarong, Kristina L.

06 April 2016

Antiviral drug resistance is a major problem in the treatment of viral infections, including influenza and hepatitis C virus (HCV). Influenza neuraminidase (NA) is a viral sialidase on the surface of the influenza virion and a primary antiviral target in influenza. Two subtypes of NA predominate in humans, N1 and N2, but different patterns of drug resistance have emerged in each subtype. To provide a framework for understanding the structural basis of subtype specific drug resistance mutations in NA, we used molecular dynamics simulations to define dynamic substrate envelopes for NA to determine how different patterns of drug resistance have emerged in N1 and N2 NA. Furthermore, we used the substrate envelope to analyze HCV NS3/4A protease inhibitors in clinical development. In addition, influenza hemagglutinin (HA) is a primary target of neutralizing antibodies against influenza. Novel broadly neutralizing antibodies (BnAbs) against the stem region of HA have been described and inhibit several influenza viral subtypes, but antibody neutralization escape mutations have emerged. We identified potential escape mutations in broadly neutralizing antibody F10 that may impact protein dynamics in HA that are critical for function. We also solved crystal structures of antibody fragments that are important for understanding the structural basis of antibody binding for influenza BnAbs. These studies can inform the design of improved therapeutic strategies against viruses by incorporating an understanding of structural elements that are critical for function, such as substrate processing and protein dynamics, into the development of novel therapeutics that are robust against resistance.

drug resistance

antibody neutralization

antivirals

influenza

Dissertations, UMMS

Antibodies, Neutralizing

Antiviral Agents

Drug Resistance, Viral

Hemagglutinins

Hepacivirus

Influenza, Human

Neuraminidase

Molecular Dynamics Simulation

Protease Inhibitors

Biochemistry

Biophysics

Cellular and Molecular Physiology

Immunoprophylaxis and Therapy

Pharmacology

Structural Biology

Virology

Virus Diseases